Reduced power bit line selection in memory circuits

ABSTRACT

A method for reducing power consumption during bit line selection in memory circuits is disclosed. According to an exemplary aspect of the method, two adjacent memory cell arrays in memory circuits generally share a row of bit-line sense amplifiers. These sense amplifiers are usually connected to a memory cell array via a number of switches. These switches specifically connect the bit lines of each of two adjacent memory cell arrays to the row of sense amplifiers. By controlling the switches, the row of sense amplifiers can be directed to serve either one of the two adjacent memory cell arrays. The switches may be connected to a bit line select control line. To achieve the desired reduction of power consumption, the present invention controls the bit-line select control line in such a way that the bit-line select control line connected to a currently active memory cell array is switched only when the next memory operation involves an adjacent memory cell array sharing the same row of bit-line sense amplifiers controlled by such bit line select control line.

CROSS REFERENCES TO RELATED APPLICATION

[0001] The present application is a divisional application which claims the benefit of priority under 35 U.S.C. § 120 from U.S. patent application Ser. No. 09/474,872 filed on Dec. 29, 1999 which, in turn, claims the benefit of priority under 35 U.S.C. § 119 from a Korean patent application, serial no. 98-61064, filed on Dec. 30, 1998.

BACKGROUND OF THE INVENTION

[0002] This invention relates in general to memory integrated circuits. In particular, this invention relates to a method and apparatus for reducing power consumption during bit line selection in memory circuits.

[0003] Memory circuits such as dynamic random access memories (DRAMs) are generally made up of a large number of memory cells arranged in the form of a matrix or array with rows and columns. FIG. 1 is a simplified block diagram of a conventional DRAM. In this typical example, memory access to the DRAM usually takes place as follows. The address buffer first reads the row address and then the column address. The addresses are passed to their respective decoders for decoding. Once decoded, the memory cell addressed outputs the stored data, which is amplified by a sense amplifier and transferred to a data output buffer by an I/O gate.

[0004] The central part of the DRAM is the memory cell array 100, which is where the data are stored. FIG. 2 is a simplified block diagram of a conventional DRAM showing an illustrative structure of the memory cell array 100. The memory cell array 100 is made up of many unit memory cells, each of which is usually individually addressable and used to store a bit. Unit memory cells are defined by word lines WLx (or rows) and bit lines BLx (or columns). The unit memory cell has a capacitor which holds the data in the form of electrical charges, and an access transistor which serves as a switch for selecting the capacitor. The transistor's gate is connected to the word line WLx. The source of the access transistors are alternately connected to the bit lines BLx. At this level, memory access begins when a word line is selected (via the decoding of a row address) thereby switching on all the access transistors connected to that word line. In other words, all the unit memory cells in that particular row are turned on. As a result, charges in the capacitor within each unit memory cell are transferred onto the bit lines causing a potential difference between the bit lines. This potential difference is detected and amplified by a sense amplifier. This amplified potential difference is then transferred to the I/O gate activated based on the column address, which in turn transfers the amplified signal to the data output buffer.

[0005] The precharge circuit plays a significant role in detecting memory data during the course of a memory access operation. In advance of a memory access and the activation of a word line, the precharge circuit charges all bit line pairs up to a certain potential which usually equals to half of the supply potential, that is, Vdd/2. The bit line pairs are short-circuited by a transistor so that they are each at an equal potential. The precharging and potential equalization by the precharging circuit is important due to the disparate difference in capacitance between the bit lines and the storage capacitor. Since the capacitance of the storage capacitor is far less than that of the bit lines, when the storage capacitor is connected to the bit lines via the access transistor, the potential of the bit line changes only slightly, typically by 100 mV. If the storage capacitor was empty, then the potential of the bit line slightly decreases; if charged, then the potential increases. The activated sense amplifier amplifies the potential difference on the two bit lines of the pair. In the first case, it draws the potential of the bit line connected to the storage capacitor down to ground and raises the potential of the other bit line up to Vdd. In the second case, the bit line connected to the storage capacitor is raised to Vdd and the other bit line decreased to ground.

[0006] Without the precharging circuit, the sense amplifier would need to amplify the absolute potential of the bit lines. However, because of the relatively small potential change between the bit lines, the amplifying process would be much less stable and unreliable.

[0007] should be noted that as the access transistors remain on by the activated word line, the accessed data are written back into the memory cells of one row. Therefore, the accessing of a single memory cell simultaneously leads to a refreshing of the whole word line. After the data output is completed, the sense amplifiers and the row and column decoders are disabled and the I/O gate block is switched off. At that time, the bit lines are still on the potentials according to the accessed data. The refreshed memory cells along the same row are disconnected from the bit lines by the disabled word line. The precharge circuit is activated to lower and increase respectively the potentials of the bit lines to Vdd/2 and equalize them again. The memory array is then ready for another memory access.

[0008] In addition, as previously mentioned, the data are stored in the form of electrical charges in the storage capacitor. Ideally, the charges in the storage capacitor should remain indefinitely. However, as a practical matter, the storage capacitor discharges over the course of time via the access transistor and its dielectric layer thereby losing the stored charges and the represented data. Hence the storage capacitor must be refreshed periodically. As discussed above, during the course of a memory access, a refresh of the memory cells within the addressed row is automatically performed. As is commonly known in the art, three refresh methods are typically used, namely, the RAS-only refresh, the CAS-before-RAS refresh, and the hidden refresh.

[0009] Due to physical constraints, the size of a memory array 100 is limited. Thus, in order to increase memory capacity, memory arrays 100 are typically stacked together to provide for the desired capacity. FIG. 3 is a simplified block diagram showing a typical structure having stacked memory arrays 100. The sense amplifiers 102 are shared by adjacent pairs of memory arrays 100 but otherwise perform the same function as mentioned above. The precharge circuit (not shown) which performs the precharge and equalization functions as mentioned above may be incorporated into a sense amplifier.

[0010] Referring to FIG. 3, a number of stacked memory cell arrays 100 (“MCAs”) are used to provide data storage. As is commonly known in the art, the number of MCAs to be used depends on the desired memory capacity and other system constraints. In FIG. 3, three representative MCAs 100 a, 100 b, 100 c are shown. Each MCA 100 has pairs of bit lines, for example, bit line pair b1(0) and b1({overscore (0)}), accessible on its either side.

[0011] Positioned between an adjacent pair of MCAs, such as MCAs 100 a, 100 b and MCAs 100 b, 100 c, are a row of bit-line sense amplifiers 102 (each a “BLSA”). The number of BLSAs 102 corresponds to the number of bit line pairs of each MCA 100. Each BLSA 102 is electrically connected to both members of the adjacent pair of MCAs such as MCAs 100 a, 100 b. More specifically, each BLSA 102 is coupled to a bit line pair, for example, b1(0) and b1({overscore (0)}) of a MCA 100 via two switches, such as transistors 104. Hence, each BLSA 102 is connected to four transistors 104, in total, two transistors for each MCA 100.

[0012] A bit-line select controller 106 (“BLSC”) is used to control the operation of each row 108 of BLSAs 102. Each BLSC 106 has two control lines 110 a, 110 b extending therefrom. One control line 110 a is connected in parallel to the gate of all the transistors 104 connecting the row 108 u of BLSAs 102 to one member MCA 100 a of the adjacent pair, while the other control line 110 b is similarly connected to all the transistors 104 connecting the row 108 u of BLSAs 102 to the other member MCA 100 b of the adjacent pair.

[0013]FIGS. 4a-c are various voltage level diagrams. Specifically, FIG. 4a shows the voltage level of successively activated word lines within one MCA(i) 100 b. For each active cycle, the potential of each word line, for example, WL(n), first goes from ground to Vpp and then back down to ground before the next active cycle begins. The voltage Vpp is a boosted voltage, that is greater than the internal power supply voltage Vdd used for the memory cell operation, needed to overcome the transistor threshold voltage Vt drop.

[0014]FIG. 4b shows the respective voltage levels of various BLS control lines 110 a, 110 b including BLS_up(i), BLS_down(i), BLS_up(i+1) and BLS_down(i−1) during active cycles when MCA(i) 100 b is activated. In this embodiment, all the BLS control lines 110 a, 110 b are initially at Vdd. For each active cycle, the potential of BLS_up(i) 100 b and BLS_down(i) 110 a for the selected array MCA(i) 100 b first goes from Vdd to Vpp and then back down to Vdd before the next active cycle begins; while the potential of BLS_up(i+1) 100 b and BLS_down(i−1) 110 a for the non-selected adjacent arrays MCA(i+1) 100 c and MCA(i−1) 10 a first drops from Vdd to ground and then back up to Vdd before the next active cycle begins. In this way, the two rows of shared bit-line sense amplifiers 108 u and 108 d are connected to array MCA(i) 100 b and disconnected from adjacent arrays MCA(i+1) 100 c and MCA(i−1) 100 a during each active cycle.

[0015]FIG. 4c similarly shows the respective voltage levels of the same BLS control lines 110 a, 110 b using different relative voltage levels. In this embodiment, all the BLS control lines 110 a, 110 b are initially at Vpp. For each active cycle, the potential of BLS_up(i) 110 b and BLS_down(i) 110 a remains the same; while the potential of BLS₁₃ up(i+1) 110 b and BLS_down(i−1) 110 a first drops from Vpp to ground and then back up to Vpp before the next active cycle begins.

[0016] As FIGS. 4b and 4 c show, during the activation of word lines within one activated MCA(i) 100 b, at least two, if not more, of the involved BLS control lines BLS_up(i) 110 b, BLS_down(i) 110 c, BLS_up(i+1) 110 d and BLS_down(i−1) 110 a have to be switched back and forth between the designated high and low voltage levels during each active cycle. Such constant switching of the BLS control lines 110 a-d during each active cycle consumes power. This type of power consumption is a particular cause for concern in modern integrated circuits. Since modern integrated circuits generally contain a high number of memory cell arrays and bit-line select controllers, the cumulative power consumption due to the constant switching of BLS control lines may reach an undesirably excessive level. Therefore, there is a need to minimize the amount of BLS control lines switching thereby reducing power consumption in memory circuits.

SUMMARY OF THE INVENTION

[0017] In accordance with the present invention, the state of a bit-line select control line connected to a currently active memory cell array is changed only when the next memory operation involves an adjacent memory cell array sharing the same row of bit-line sense amplifiers connected to such bit line select control line. Otherwise, the state of the bit-line select control line is not switched even when the array to which it connects is no longer active.

[0018] An exemplary embodiment of the present invention includes a memory circuit having a number of memory cell arrays and a number of rows of bit-line sense amplifiers. Each row of the bit-line sense amplifiers is disposed between and coupled to a pair of adjacent memory cell arrays. The exemplary embodiment further includes a number of bit-line select controllers. Each bit-line select controller includes a bit-line select control line extending therefrom and coupling to one of the rows of bit-line sense amplifiers for controlling the operation thereof Each bit-line select control line is used to control the coupling between a row of bit-line sense amplifiers and one member of a pair of adjacent memory cell arrays. Once switched on, the bit-line select control line is switched off only when the other member of the pair of adjacent memory cell arrays is to be activated.

[0019] Another exemplary embodiment of the present invention further includes a method of operating a memory circuit. The method includes the steps of disposing a number of bit-line sense amplifiers between a pair of adjacent arrays of memory cells; activating one member of the pair of adjacent arrays of memory cells; coupling the bit-line sense amplifiers to one member of the pair of adjacent arrays of memory cells by turning on a number of coupling switches; and keeping the coupling switches on until the other member of the pair of adjacent arrays of memory cells is activated.

[0020] Reference to the remaining portions of the specification, including the drawings and claims, will realize other features and advantages of the present invention. Further features and advantages of the present invention, as well as the structure and operation of various embodiments of the present invention, are described in detail below with respect to accompanying drawings. In the drawings, like reference numbers indicate identical or functionally similar elements and letters at the end of reference numbers are used for ease of reference to further differentiate each of a number of identical or functionally similar elements.

BRIEF DESCRIPTION OF THE DRAWINGS

[0021]FIG. 1 is a simplified block diagram of a conventional DRAM;

[0022]FIG. 2 is a simplified block diagram of a conventional DRAM showing an illustrative structure of the memory cell array;

[0023]FIG. 3 is a simplified block diagram showing a typical structure having stacked memory arrays;

[0024]FIG. 4a is a diagram showing the voltage level of successively activated word lines within one MCA during active cycles;

[0025]FIG. 4b is a diagram showing the respective voltage levels of various BLS control lines during active cycles when only one MCA is activated;

[0026]FIG. 4c is a diagram similar to FIG. 4b showing the respective voltage levels of the same BLS control lines during active cycles using different relative voltage levels;

[0027]FIG. 5a is a state transition diagram showing the state of transition of a BLS control line BLS_up(i) in a first preferred embodiment in accordance with the present invention;

[0028]FIG. 5b is a state transition diagram showing the state of transition of a BLS control line BLS_down(i−1) in a first preferred embodiment in accordance with the present invention;

[0029]FIGS. 6a and 6 b show the voltage levels of various BLS control lines during a self-refresh cycle of a MCA in accordance with the present invention;

[0030]FIGS. 7a and 7 b show the voltage levels of various BLS control lines during successive active cycles in the same MCA in accordance with the present invention;

[0031]FIGS. 8a, 8 b, and 8 c show the voltage levels of various BLS control lines during normal mode in accordance with the present invention;

[0032]FIGS. 9a and 9 b show two state diagrams illustrating the state of transition of two BLS control lines in a second embodiment in accordance with the present invention;

[0033]FIG. 10 is a simplified block diagram showing a memory circuit in accordance with the present invention;

[0034]FIG. 11 is a schematic block diagram showing a preferred embodiment of the BLS control in accordance with control in accordance with the present invention;

[0035]FIG. 12 is a schematic block diagram further showing the components of an element of a preferred embodiment of the BLS control in accordance with the present invention;

[0036]FIG. 13 is a schematic block diagram showing an alternative embodiment of the BLS control in accordance with the present invention;

[0037]FIG. 14 is a schematic block diagram further showing the components of an element of a preferred embodiment of the BLS control in accordance with the present invention;

[0038]FIG. 15 shows a precharge charge circuit integrated within a bit-line sense amplifier and shared by bit lines from adjacent memory cell arrays; and

[0039]FIG. 16 shows two precharge circuits each independently serving bit lines from a memory cell array.

DESCRIPTION OF THE SPECIFIC EMBODIMENTS

[0040] The present invention provides a new and improved method and apparatus to control and reduce switching of bit-line select control lines in memory circuit. The general operation of a preferred embodiment of the present invention will now be described. Referring to FIG. 3, when a specific MCA 100 b is accessed, the two rows 108 u and 108 d of BLSAs 102 directly connected to that MCA(i) 100 b are activated by the BLS controls 106 via the BLS control lines, BLS_up(i) 110 b and BLS down(i) 110 c, and are dedicated to serve exclusively that particular MCA(i) 100 b. The BLS controls 106 continue to keep the BLSAs 102 activated in their respective current state pending the next memory operation. A BLS control line 100 a controlling the BLSA 102 is directed to change its state only when an adjacent MCA sharing the same BLSAs 102 is to be accessed next. For example, if the adjacent MCA (i−1) 100 a is required to be accessed next, BLS control 16 via control line, BLS_down(i−1) 110 a, activates all the transistors 104 connecting the row 108 u of BLSAs 102 to MCA (i−1) 100 a and via control line, BLS_up(i) 110 b, deactivates all the transistors 104 coupled between the row 108 d of BLSAs 102 and MCA(i) 100 b. The BLS control line, BLS_down(i) 110 c, on the other hand, remains unchanged since MCA (i−1) does not share the same row 108 d of BLSAs 102 as that controlled by BLS_down(i) 110 c.

[0041] Referring to FIGS. 5a and 5 b there are shown two state diagrams illustrating the state of transition of the BLS control lines in a first preferred embodiment according to the present invention. FIGS. 5a and 5 b respectively show the state of transition of the two BLS control lines, BLS_up(i) 110 b and BLS_down(i−1) 110 a, controlled by BLS control 106 in accordance with the operation of MCA(i) 100 b and MCA(i−1) 100 a. It should be noted that as commonly understood in the art MCA(i) 100 b and MCA(i−1) 100 a cannot be activated simultaneously. It should be further noted that BLS_down(i) 110 c and BLS_up(i+1) 110 d are functionally equivalent to BLS_down(i−1) 110 a and BLS_up(i) 110 b respectively. Hence, it should be understood that FIG. 5a and FIG. 5b similarly apply to BLS_up(i+1) 110 d and BLS_down(i) 110 c respectively.

[0042]FIG. 5a shows the state of transition of the BLS control line BLS_up(i) 110 b using MCA(i) 100 b as a central point of reference. When the BLS control 106 is first turned on, BLS_up(i) 110 b is initialized to Vdd. Once initialized, BLS control 106 waits to determine which MCA 100 is to be accessed next. If MCA(i) 100 b is to be activated, then BLS_up(i) 110 b is charged to Vpp. BLS_up(i) 110 b is to remain at Vpp if the next operation requires MCA(i) 100 b to be either precharged or activated or self-refreshed; but if the next operation requires MCA(i−1) 100 a to be activated, then BLS_up(i) 110 b is to be dropped to ground. BLS_up(i) 110 b is to remain at ground if the next operation indicates that MCA(i−1) 100 a is to engage in a self-refresh cycle; but if the next operation indicates that the self-refresh cycle of the MCA(i−1) 100 a is completed or that the MCA(i−1) 100 a is to be precharged, then BLS_up(i) 110 b is to be raised to Vdd. Initially, while BLS_up(i) 110 b is at Vdd, if the next operation shows that MCA(i−1) 100 a is to be activated, then BLS_up(i) 110 b is to be dropped to ground.

[0043]FIG. 5b similarly shows the corresponding state of transition of the BLS control line BLS_down(i−1) 110 a in concert with the transition of BLS_up(i) 110 b shown in FIG. 5a. The same explanation as given for FIG. 5a similarly applies. For example, as shown in FIG. 5a, when MCA(i) 100 b is activated (represented by transition paths A or D), BLS_up(i) 100 b is charged to Vpp; accordingly, as shown in FIG. 5b, when MCA(i) 100 b is activated (represented by transition path B), BLS_down(i−1) 110 a is dropped to ground.

[0044] It should be noted that while only BLS control 106 and its BLS control lines, BLS_up(i) 110 b and BLS_down(i−1) 110 a, are explained in detail, the same principles apply to other BLS controls and their respective BLS control lines, such as BLS control lines, BLS_up(i+1) 110 d and BLS_down(i) 110 c.

[0045]FIG. 6a shows the voltage levels of various BLS control lines including, BLS_up(i) 110 b, BLS_down(i) 110 c, BLS_up(i+1) 110 d, and BLS_down(i−1) 110 a, during a self-refresh cycle of MCA(i) 100 b in accordance with the present invention. As FIG. 6a shows, during the self-refresh cycle of MCA(i) 100 b, once the BLS control lines reach their respective voltage levels, i.e., Vpp for BLS_up(i) 110 b and BLS_down(i) 100 c and ground for BLS_up(i+1) 110 d, and BLS_down(i−1) 110 a, they remain there until the self-refresh cycle is completed. During the self-refresh cycle, it is possible to keep BLS_up(i+1) 110 d and BLS_down(i−1) 110 a at ground because the location of the next word line access is always within MCA(i) 100 b. Hence, BLS_up(i+1) 110 d and BLS_down(i−1) 110 a do not need to be precharged since MCA(i−1) 100 a and MCA(i+1) 100 c will not be accessed when MCA(i) 100 b is being self-refreshed. This is to be contrasted with FIG. 4b where those same BLS control lines have to be switched back and forth during each active cycle regardless of the fact that only MCA(i) 100 b is activated.

[0046]FIG. 7a shows the voltage levels of various BLS controls lines including, BLS_up(i) 110 b, BLS_down(i) 110 c, BLS_down(i+1) 110 f, BLS_up(i+1) 110 d, BLS_up(i−1) 110 e and BLS_down(i−1) 110 a, during successive active cycles in the same MCA(i) 100 b in accordance with the present invention. Following the state transition diagrams as shown in FIGS. 5a and 5 b, during successive active cycles in the same MCA(i) 100 b, the BLS control lines, BLS_up(i) 110 b and BLS_down(i) 110 c, are pulled up to Vpp only once and remain there, while BLS_down(i−1) 110 a and BLS_up(i+1) 110 d are pulled to ground at the beginning of each active cycle and raised to Vdd during each precharge.

[0047] It is worth noting that the behavior of BLS_up(i+1) 110 d and BLS_down(i−1) 110 a in FIG. 7a is different from that shown in FIG. 6a. In FIG. 7a, there is shown successive active cycles in the same MCA(i) 100 b. It is to be understood that unlike a self-refresh cycle shown in FIG. 6a, these successive active cycles in FIG. 7a do not necessarily all have to take place in MCA(i) 100 b, but that for illustrative purposes only, these successive active cycles all incidentally take place in MCA(i) 100 b. Therefore, BLS_up(i+1) 110 d and BLS_down(i−1) 110 a have to be raised to Vdd to allow the bit lines in the unselected arrays MCA(i−1) 100 a and MCA (i+1) 100 c to be precharged at a specified voltage thereby providing for the possibility that the next memory operation may take place in either MCA(i−1) 100 a or MCA(i+1) 100 c. This is to be contrasted with FIG. 6a where BLS_up(i+1) 110 d and BLS_down(i−1) 110 a are only pulled up to Vdd at the end of the self-refresh cycle. That is because those bit lines do not need to be precharged since MCA(i−1) 100 a and MCA(i+1) 100 c will never be active when MCA(i) 100 b is engaged in a self-refresh cycle. BLS_up(i+1) 110 d and BLS_down(i−1) 110 a only need to be precharged when there is a possibility that the next memory operation might involve either MCA(i−1) 100 a or MCA(i+1) 100 c.

[0048] In addition, BLS_down(i+1) 110 f and BLS_up(i−1) 110 e remain constant at Vdd. This is due to the fact that when MCA(i) 100 b is active, it does not affect either of those two BLS control lines because those lines are not directly connected to any of the BLSAs 102 used by MCA(i) 100 b. Furthermore, it is also shown that when a MCA(j) is active, it does not affect any of the BLS control lines, BLS_up(i) 110 b, BLS_down(i) 110 c, BLS_down(i+1) 110 f, BLS_up(i+1) 110 d, BLS_up(i−1) 110 e and BLS_down(i−1) 110 a, provided that MCA(j) is not MCA(i) 100 b or either one of MCA(i)'s 100 b adjacent neighbors, MCA(i−1) 100 a and MCA(i+1) 110 b.

[0049]FIGS. 8a-c show the voltage levels of various BLS controls lines including, BLS_up(i) 110 b, BLS down(i) 100 c, BLS_down(i+1) 110 f, BLS_up(i+1) 110 d, BLS_up(i−1) 110 e and BLS_down(i−1) 110 a, during a normal mode of operation of a preferred embodiment in accordance with the present invention. A normal mode of operation is generally defined as random access in different MCAs 100. All the BLS control lines shown behave in accordance with the state transition diagrams in FIGS. 5a and 5 b. FIG. 8a shows the voltage levels of BLS_up(i) 110 b and BLS_down(i) 110 c which are directly connected to MCA(i) 100 b. Both BLS_up(i) 110 b and BLS_down(i) 110 c are pulled up to Vpp from Vdd when MCA(i) 100 b is activated. When the access to MCA(i) 100 b is followed by an access to an adjacent MCA 100, i.e. MCA(i+1) 100 c, BLS_up(i) 110 b remains at Vpp while BLS_down(i) 110 c drops down to ground. BLS_up(i) 110 b and BLS_down(i) 110 c behave differently when MCA(i+1) 100 c is activated because BLS_up(i) 110 b is not directly connected to the row 108 d of BLSAs 102 shared by MCA(i+1) 100 c. During the precharge of MCA(i+1) 100 c, BLS_up(i) 110 b remains at Vpp and BLS_down(i) 110 c is pulled up to Vdd. Then, when MCA(i−1) 100 a is activated, BLS_up(i) 110 b drops down to ground while BLS_down(i) 110 c remains constant at Vdd. In that case, BLS_down(i) 110 c is not directly connected to the row 108 u of BLSA 102 shared by MCA(i−1) 100 a.

[0050]FIG. 8b shows the voltage levels of BLS_down(i+1) 110 f and BLS_up(i+1) 110 d along the same time line. When MCA(i) 100 b is activated, BLS_down(i+1) 110 f remains at Vdd while BLS_up(i+1) 110 d is pulled down to ground. Again, this is because BLS_up(i+1) 110 d is directly connected to the row 108 d of BLSAs 102 shared by MCA(i) 100 b. BLS_up(i+1) 110 d is pulled back up to Vdd during the precharge of MCA(i) 100 b. When MCA(i+1) 100 c is then activated, both BLS_up(i+1) 110 d and BLS_down(i+1) 110 f are pulled up to Vpp. Subsequently, when the activation of MCA(i−1) 100 a immediately follows, both BLS_up(i+1) 110 d and BLS_down(i+1) 110 f remains at Vpp, since neither of those two BLS control lines is directly connected to the row 108 u of BLSAs 102 shared by MCA(i−1) 100 a. Finally, when MCA(i) 100 b is activated, BLS_down(i+1) 110 f continues to remain at Vpp while BLS_up(i+1) 110 d is pulled down to ground.

[0051]FIG. 8c shows the voltage levels of BLS_down(i−1) 110 a and BLS_up(i−1) 110 e along the same time line. When MCA(i) 100 b is activated, BLS_up(i−1) 110 e remains at Vdd while BLS_down(i−1) 110 a is pulled down to ground. BLS_down(i−1) 110 a is then pulled back up to Vdd during the precharge of MCA(i) 100 b. When MCA(i+1) 100 c is next activated, both BLS_up(i−1) 110 e and BLS_down(i−1) 110 a remain at Vdd, since neither of those two BLS control lines is directly connected to the row 108 d of BLSAs 102 shared by MCA(i+1) 100 c. When MCA(i−1) 100 a is then activated, both BLS_up(i−1) 110 c and BLS down(i−1) 110 a are pulled up to Vpp. Finally, when MCA(i) 100 b is activated, BLS_up(i−1) 110 e again remains at Vdd while BLS_down(i−1) 110 a is pulled down to ground.

[0052] Referring to FIGS. 9a and 9 b there are shown two state diagrams illustrating the state of transition of the BLS control lines in a second preferred embodiment according to the present invention. FIGS. 9a and 9 b are respectively similar to FIGS. 5a and 5 b showing the state of transition of the two BLS control lines, BLS_up(i) 110 b and BLS_down(i−1) 110 a, controlled by BLS control 106 in accordance with the operation of MCA(i) 100 b and MCA(i−1) 100 a. As shown in FIGS. 9a and 9 b, the difference is that BLS_up(i) 110 b and BLS_down(i−1) 110 a are initially set to Vpp as opposed to Vdd.

[0053]FIG. 6b shows the voltage levels of various BLS control lines including, BLS_up(i) 110 b, BLS_down(i) 110 c, BLS_up(i+1) 110 d, and BLS_down(i−1) 110 a, during a self-refresh cycle of MCA(i) 100 b in accordance with a second embodiment of the present invention. As FIG. 6b shows, during the self-refresh cycle of MCA(i) 100 b, BLS_up(i) 110 b and BLS_down(i) 110 c remain constant at Vpp and BLS_up(i+1) 110 d, and BLS_down(i−1) 110 a are pulled to ground and remain there until the self-refresh cycle is completed. This is to be contrasted with FIG. 4c where BLS_up(i+1) 110 d, and BLS_down(i−1) 110 a have to be switched between Vpp and ground during each active cycle regardless of the fact that only MCA(i) 100 b is activated.

[0054]FIG. 7b shows the voltage levels of various BLS controls lines including, BLS_up(i) 110 b, BLS_down(i) 110 c, BLS_down(i+1) 110 f, BLS_up(i+1) 110 d, BLS_up(i−1) 110 e and BLS_down(i−1) 110 a, during successive active cycles in the same MCA(i) 100 b in accordance with a second embodiment of the present invention. Following the state transition diagrams as shown in FIGS. 9a and 9 b, during successive active cycles in the same MCA(i) 100 b, the BLS control lines, BLS_up(i) 110 b and BLS_down(i) 110 c, remain constant at Vpp throughout, while BLS_down(i−1) 110 a and BLS_up(i+1) 110 d are pulled to ground at the beginning of each active cycle and raised to Vdd during each precharge. FIG. 15 shows a precharge circuit 130 integrated within a BLSA 102. This precharge circuit 130 is shared by the bit lines, for example, b1(1) and b1({overscore (1)}), from both MCA(i) 100 b and MCA(i+1) 100 c. In this embodiment, as explained in connection with FIG. 7a, BLS_up(i+1) 110 d is raised to Vdd during precharge to allow the shared equalization and precharge circuits within each BLSA 102 to maintain the bit lines in the unselected MCA(i+1) 100 c at a specified precharge voltage to avoid floating bit lines.

[0055] In an alternative embodiment (not shown), switching of the BLS control lines may be further reduced by letting BLS_up(i+1) 110 d to stay at ground even during normal mode, which is when MCAs 100 are randomly accessed. However, in order to allow BLS_up(i+1) 110 d to remain at ground during normal mode, a separate equalization and precharge circuit 140 is required on either side of a BLSA 102 to maintain the bit lines of MCA(i+1) 100 c at a specified voltage, as shown in FIG. 16. This is possible because the transistors 104 do not affect the precharging of the bit lines. Hence, there would be no sharing of the equalization and precharge circuit 140, thus resulting in a need for more surface area for the integrated circuits.

[0056] Also shown in FIG. 7b, as expected, BLS_down(i+1) 119 f and BLS_up(i−1) 110 e remain constant at Vpp. This is due to the fact that when MCA(i) 100 b is active, it does not affect either of those two BLS control lines because those lines are not directly connected to any of the BLSAs 102 used by MCA(i) 100 b. Furthermore, it is also shown that when a MCA(j) is active, it does not affect any of the BLS control lines, BLS_up(i) 110 b, BLS_down(i) 110 c, BLS_down(i+1) 110 f, BLS_up(i+1) 110 d, BLS_up(i−1) 119 e and BLS_down(i−1) 110 a, provided that MCA(j) is not MCA(i) 100 b or either one of MCA(i)'s 100 b adjacent neighbors, MCA(i−1) 100 a and MCA(i+1) 100 e.

[0057] Hence, as shown by FIGS. 6-8, by using the present invention, excessive and unnecessary switching of BLS control lines can be avoided thereby reducing significant amount of power consumption.

[0058]FIG. 10 is a simplified block diagram showing a memory circuit in accordance with the present invention. FIGS. 11-14 show various embodiments of the BLS control 106 in accordance with the present invention. The BLS control 106 controls the transitional states of the BLS control lines thereby implementing the proper switching of the BLS control lines in accordance with the present invention.

[0059] The memory circuit shown in FIG. 10 operates as follows. The memory address provided by logic circuitry is stored in the address buffer 140. The memory operation command provided by logic circuitry is decoded by the command decoder 142. The respective outputs from the address buffer 140 and command decoder 142 are used by the row control 144 to generate certain signals to control the BLS controls 106 and the W/L controls 146. The W/L controls 146 control which one of the memory cell arrays 100 should be activated and the BLS controls 106 correspondingly activate the appropriate the bit-line sense amplifier arrays associated with the activated memory cell arrays 100 to implement the desired memory operation. In addition, if the memory operation command indicates a self-refresh operation, the self-refresh control 148 is also used to control the row control 144, the BLS controls 106 and the W/L controls 146 to achieve the desired self-refresh operation.

[0060] A first preferred embodiment of the BLS control 106 is shown in FIG. 11. It should be noted that FIG. 11 only shows the circuit for controlling one BLS control line. Since a BLS control 106 has two BLS control lines, it should be understood that a complete BLS control 106 should contain at least two such circuits. The BLS control 106 includes a control logic block 112, a transistor MP1, a transistor MP2 and a transistor MN1. The control logic block 112 receives the following signals from the memory circuit control logic: ACT signaling activation of that array, PCG indicating precharge operation, Address Information and Self_refresh_flag. These control logic block 112 signals are uniformly available to all the BLS controls 106, as shown in FIG. 10, and are commonly generated in most dynamic RAMs. Using these input signals, the control logic block 112 outputs the following signals: Precharge_bls, Activate_bls and Turn_bls_off. Transistor MP1 is preferably a p-channel transistor. The gate of transistor MP1 is connected to the signal, Activate_bls, the source is connected to a power supply Vpp, and the drain is connected to the BLS control line 110. Transistor MP2 is also preferably a p-channel transistor. The gate of transistor MP2 is connected to the output signal, Precharge_bls, the source is connected to a power supply Vdd, and the drain is connected to the BLS control line 110. Transistor MN1 is preferably a n-channel transistor. The gate of transistor MN1 is connected to the signal, Turn_bls_off, the source is connected to the BLS control line 110, and the drain is connected to ground. The output signals, Precharge_bls, Activate_bls and Turn_bls_off, are used to control the transistors MP1, MP2 and MN1 which, in turn, determine the state of the BLS control line 118. For example, focusing on BLS_up(i) 110 b, if MCA(i) 100 b is to be activated, then the output signal, Activate_bls, turns on transistor MP1 thereby pulling BLS_up(i) 110 b to Vpp; if MCA(i−1) 100 a is to be activated instead, then the signal, Turn_bls_off, turns on transistor MN1 thereby pulling BLS_up(i) 110 b to ground; and if MCA(i−1) 100 a is to be precharged, then the signal, Precharge_bls, switches on transistor MP2 thereby pulling BLS_up(i) 110 b to Vdd.

[0061]FIG. 12 is a schematic block diagram further showing the components of the control logic block 112. The control logic block 112 includes an activate_bls generator 114 and a precharge_bls & turn_bls_off generator 116. The activate_bls generator 114 accepts as input the two signals, This_block_activation_flag and Opposite_block_activation_flag, to produce the Activate_bls signal. The precharge_bls & turn_bls_off generator 116 accepts as input the Self_refresh_flag. This_block_activation_flag and Opposite_block_activation_flag are used to produce the Precharge_bls and the Turn_bls_off signals. This_block_activation_flag and Opposite_block_activation_flag are pre-decoded based on the ACT, PCG, Address Information and Self_refresh_flag signals.

[0062]FIG. 14 is a block diagram schematic further showing the components of the Precharge_bls & turn_bls_off generator 116 shown in FIG. 12. The Precharge_bls & turn_bls_off generator 116 includes a Precharge Control Block 118, a Turn_off Control Block 120, and a NAND gate 122. The Precharge Control Block 118 receives the Opposite_activation_flag and the Self_refresh_flag as input and directs its output to the input of the NAND gate 122. The NAND gate 122 accepts the output from the Precharge Control Block 118 and the Activate_bls generator 114 to produce the Precharge_bls signal at its output. The Turn_off Control Block 120 receives the Opposite_block_activation_flag and generates the Turn_bls_off signal.

[0063]FIG. 13 is a schematic block diagram showing an alternative embodiment of the BLS control 106 as shown in FIG. 11. The Self_refresh_flag is fed separately into a buffer 118. The output of the buffer 118 is connected to the gate of a transistor MP3. Transistor MP3 is connected in series between the power supply Vdd and transistor MP2.

[0064] It is understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application and scope of the appended claims. All publications, patents, and patent applications cited herein are hereby incorporated by reference for all purposes in their entirety. 

What is claimed is:
 1. A method of operating a memory circuit, comprising the steps of: disposing a plurality of bit-line sense amplifiers between a pair of adjacent arrays of memory cells; activating a first one of said pair of adjacent arrays of memory cells; coupling said plurality of bit-line sense amplifiers to said first one of said pair of adjacent arrays of memory cells by turning on a plurality of coupling switches; and keeping said plurality of coupling switches on until a second one of said pair of adjacent arrays of memory cells is activated. 